System for generating difference in speed between left and right wheels of vehicle

Abstract

A gearbox mounted between axles for left and right follower wheels of a vehicle includes a countershaft parallel to the axles. The countershaft is rotated at a speed greater than those of the right axle by speed-increasing gears. The countershaft and the left axle are capable of being connected to each other through first and second shifting gears and a first hydraulic clutch and through third and fourth shifting gears and a second hydraulic clutch. The first and second hydraulic clutches are disposed back-to-back between the first and third shifting gears and therefore, the size of the entire gearbox can be reduced. Moreover, since the first and second hydraulic clutches are mounted on the countershaft which is rotated at the higher speed, the necessary torque transmitting capacities of the first and second hydraulic clutches can be decreased, leading to reduced sizes of the first and second hydraulic clutches.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a system for generating a difference in speed between left and right wheels of a vehicle by connecting the left and right wheels to each other by a gearbox.

2. Description of the Related Art

A left and right wheel speed difference generating system is disclosed in Japanese Patent Application Laid-open No. 5-131855.

With the above left and right wheel speed difference generating system, by controlling the engaged states of a speed-increasing clutch and a speed-decreasing clutch which are mounted in the gearbox, torque can be transmitted from an inner wheel to an outer wheel during turning of the vehicle to generate a driving force in the outer wheel and to generate a braking force in the inner wheel, thereby enhancing the turning performance, and torque can be transmitted from the outer wheel to the inner wheel during turning of the vehicle to generate a braking force in the outer wheel and to generate a driving force in the inner wheel, thereby enhancing high-speed stability.

The known wheel speed difference generating system has a structure in which the speed-increasing clutch and the speed-decreasing clutch are coaxially disposed adjacent one another between input and output shafts or two output shafts of a parallel two-shaft gearbox. A shifting gear is integrally provided around an outer periphery of a clutch outer portion, and a clutch inner portion is connected to the input shaft or the output shaft.

If the speed-increasing clutch and the speed-decreasing clutch are mounted on the input shaft or the output shaft of the gearbox in the above manner, the following problem is encountered: the torque of the input shaft or the output shaft is transmitted directly to the clutch and for this reason, the necessary torque transmitting capacity of the clutch is increased, resulting in an increased size of the gearbox. Moreover, another problem is that since the shifting gear is provided around the outer periphery of the clutch outer portion, the outside diameter of the clutch is further increased to bring about a further increase in size of the gearbox.

SUMMARY OF THE INVENTION

Accordingly, it is an object of the present invention to reduce the size of the gearbox in the left and right wheel speed difference generating system.

To achieve the above object, according to a first aspect and feature of the present invention, there is provided a system for generating a difference in speed between left and right wheels of a vehicle, by connecting the left and right wheels to each other by a gearbox, wherein the gearbox includes: a countershaft disposed in parallel with axles of the left and right wheels; first and second speed-increasing gears for increasing the number of rotations of one of the axles to transmit the rotation of the one axle to the countershaft; a first shifting gear relatively rotatably carried on the countershaft; a second shifting gear fixedly mounted on the other axle and meshed with the first shifting gear; a third shifting gear relatively rotatably carried on the countershaft; a fourth shifting gear fixedly mounted on the other axle and meshed with the third shifting gear; a first clutch mounted on the countershaft for coupling the first shifting gear to the countershaft; and a second clutch mounted on the countershaft for coupling the third shifting gear to the countershaft, the first and second clutches being disposed adjacent one another between the first and third shifting gears.

With such an arrangement, the first and second clutches are mounted on the countershaft to which a smaller torque is transmitted because the countershaft is rotated at a speed greater than that of the axles. Therefore, the torque transmitting capacity of the clutch can be decreased to reduce the size of the clutch, as compared with the case where the first and second clutches are mounted on the axles to which a larger torque is transmitted because the axles are rotated at a lower speed. Moreover, since the first and second clutches are disposed adjacent one another between the first and third shifting gears, the size of the entire gearbox can be also reduced to provide a reduced empty weight and an enhanced load-carrying ability of the vehicle.

According to a second aspect and feature of the present invention, in addition to the first feature, the outside diameter of the first shifting gear is less than the outside diameter of a clutch outer portion of the first clutch, and the outside diameter of the third shifting gear is less than the outside diameter of a clutch outer portion of the second clutch.

With the second feature, the radial sizes of the first and second clutches can be reduced to provide a reduction in size of the entire gearbox.

According to a third aspect and feature of the present invention, in addition to the first feature, the wheel speed difference generating system further includes a hydraulic pump for supplying a working oil to the first and second clutches, which is driven by the countershaft.

With the third feature, the number of revolutions of the hydraulic pump can be increased by driving the hydraulic pump by the countershaft to insure a sufficient amount of oil is discharged even during traveling of the vehicle at a low speed, as compared with the case where the hydraulic pump is driven by the axle.

The above and other objects, features and advantages of the invention will become apparent from the following detailed description of a preferred embodiment taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic illustration of the entire arrangement of a front engine and front drive vehicle equipped with a left and right wheel speed difference generating system;

FIG. 2 is a skeleton illustration of a gearbox;

FIG. 3 is a sectional view of right half of the gearbox; and

FIG. 4 is a sectional view of left half of the gearbox.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention will now be described by way of an embodiment with reference to the accompanying drawings.

FIGS. 1 to 4 illustrate an embodiment of the present invention. As shown in FIGS. 1 and 2, a transmission M is connected to a right end of an engine E mounted horizontally at a front portion of a vehicle body, and a left front wheel W_FL and a right front wheel W_FR as driven wheels are driven by the engine E and the transmission M. A gearbox 2 is mounted between a left rear wheel W_RL and a right rear wheel W_RR as follower wheels for connecting the left and right rear wheels W_RL and W_RR, so that the left and right rear wheels W_RL and W_RR are rotated at different speeds. The gearbox 2 is provided with a first hydraulic clutch 3_R and a second hydraulic clutch 3_L. When the first hydraulic clutch 3_R is brought into an engaged state, the number of revolutions of the right rear wheel W_RR is decreased, while the number of revolutions of the left rear wheel W_RL is increased. When the second hydraulic clutch 3_L is brought into an engaged state, the number of revolutions of the left rear wheel W_RL is decreased, while the number of revolutions of the right rear wheel W_RR is increased.

The structure of the gearbox 3 will be described below with reference to FIGS. 2 and 3.

The gearbox 2 includes a center housing 4, and a left housing 5_L and a right housing 5_R are coupled to left and right opposite end faces of the center housing 4. A right axle 1_R is carried in the right housing 5_R with ball bearings 6, 6 interposed therebetween, and a left axle 1_L is carried in a pump cover 8 with ball bearings interposed therebetween. The pump cover 8 is fixed within the left housing 5_L through bolts 7 with a roller bearing 10 incorporated in a recess which opens into an end face of the right axle 1_R. Therefore, the left and right axles 1_L and 1_R are located coaxially and can be rotated at different speeds.

A countershaft 11 is supported at its right and left ends in the pump cover 8 and the right housing 5_R through ball bearings 12 and 13, respectively. The counter shaft 11 is disposed parallel to the left and right axles 1_L and 1_R and above the left and right axles 1_L and 1_R. A first small-diameter gear 14 (having a number X₁ of teeth) is spline-coupled to the right end of the countershaft 11 and is meshed with a second large-diameter speed-increasing gear 14 (having a number X₂ of teeth (X₁ <X₂)) which is integrally formed on the left end of the right axle 1_R, and thus, the countershaft 11 is rotated at a higher speed than that of the right axle 1_R.

A first shifting gear 17 is relatively rotatably carried on a right portion of the countershaft 11 with a needle bearing 16 interposed therebetween, and is meshed with a second shifting gear 18 which is spline-coupled to the right end of the left axle 1_L. The numbers of teeth Y₁ and Y₂ of the first and second shifting gears 17 and 18 are set at Y₁ <Y₂, respectively. A third shifting gear 20 is relatively rotatably carried on a left portion of the countershaft 11 with a needle bearing 19 interposed therebetween, and is meshed with a fourth shifting gear 21 which is spline-coupled to the left portion of the left axle 1_L. The numbers of teeth Y₃ and Y₄ of the third and fourth shifting gears 20 and 21 are set at Y₃ <Y₄, respectively.

The structure of the first hydraulic clutch 3_R adapted to couple the first shifting gear 17 to the countershaft 11 will be described with reference to FIG. 3.

The first hydraulic clutch 3_R includes a clutch outer portion 22_R which is rotatable in unison with the first shifting gear 17, a clutch inner portion 23_R spline-coupled to the countershaft 11, a plurality of clutch plates 24_R slidably carried on the clutch outer portion 22_R, a plurality of clutch disks 25_R slidably carried on the clutch inner portion 23_R and alternately superposed one upon the other, a pressure plate 26_R slidably spline-coupled to the clutch inner portion 23_R to bring the clutch plates 24_R and the clutch disks 25_R into pressure contact with one another, and a clutch spring 27_R compressed between the pressure plate 26_R and the clutch inner portion 23_R.

A main piston 29_R, a reaction piston 30_R and an assist piston 31_R are axially disposed in an annular cylinder 28_R formed in the center housing 4, and a thrust bearing 32_R is disposed between the main piston 29_R and the clutch disk 25_R disposed at an end. A first clutch oil chamber 33_R is defined between the assist piston 31_R and a bottom of the cylinder 28_R, and a second clutch oil chamber 34_R is defined between the main piston 29_R and the reaction piston 30_R to communicate with the first clutch oil chamber 33_R.

The structure of the second hydraulic clutch 3_L shown in FIG. 4 is substantially mirror-symmetrical with the structure of the first hydraulic clutch 3_R and hence, the repeated description thereof is omitted. Each of the characters affixed to the members or portions of the second hydraulic clutch 3_L has a suffix "_L " substituted for a suffix "_R " attached to each of the characters affixed to the corresponding members or portions of the first hydraulic clutch 3_R.

A hydraulic pump 35 is mounted in such a manner that it is sandwiched between the pump cover 8 and the left housing 5_L, and an oil discharged from the hydraulic pump is supplied via a hydraulic circuit to the first and second hydraulic clutches 3_R and 3_L and the first clutch oil chambers 33_R and 33_L.

The working oil supplied to the first clutch oil chamber 33_R in the first hydraulic clutch 3_R is also transmitted to the second clutch oil chamber 34_R, and a resultant force of an urging force of the assist piston 31_R and an urging force of the main piston 29_R is applied to the pressure plate 26_R through the thrust bearing 32_R to bring the clutch plates 24_R and the clutch disks 25_R into pressure contact with one another. As a result, the first shifting gear 17 is coupled to the countershaft 11 through the clutch outer portion 22_R, the clutch plates 24_R, the clutch disks 25_R and the clutch inner portion 23_R. Likewise, when the working oil is supplied to the first clutch oil chamber 33_L in the second hydraulic clutch 3_L, the third shifting gear 20 is coupled to the countershaft 11.

When the first hydraulic clutch 3_R is brought into an engaged state, the right axle 1_R is connected to the left axle 1_L through the second speed-increasing gear 15, the first speed-increasing gear 14, the countershaft 11, the first hydraulic clutch 3_R, the first shifting gear 17 and the second shifting gear 18. At this time, the speed-increasing degree in the transmission of the rotation from the first shifting gear 15 to the first speed-increasing gear 14 is set greater than the speed-decreasing degree in the transmission of the rotation from the first shifting gear 17 to the second shifting gear 18 and hence, the number of revolutions of the left rear wheel W_RL is increased relative to the number of revolutions of the right rear wheel W_RR. Thus, if the first hydraulic clutch 3_R is brought into its engaged state, for example, during straight traveling of the vehicle, the number of revolutions of the right rear wheel W_RR is decreased, while the number of revolutions of the left rear wheel W_RL is increased.

If the second hydraulic clutch 3_L is brought into its engaged state, the left axle 1_L is connected to the right axle 1_R through the fourth shifting gear 21, the third shifting gear 20, the second hydraulic clutch 3_L, the countershaft 11, the first speed-increasing gear 14 and the second speed-increasing gear 15. At this time, the speed-increasing degree in the transmission of the rotation from the fourth shifting gear 21 to the third shifting gear 20 is set greater than the speed-increasing degree in the transmission of the revolutions from the first shifting gear 14 to the second speed-increasing gear 15 and hence, the number of revolutions of the right rear wheel W_RR is increased relative to the number of revolutions of the left rear wheel W_RL. Thus, if the second hydraulic clutch 3_L is brought into its engaged state, for example, during straight traveling of the vehicle, the number of revolutions of the left rear wheel W_RL is decreased, while the number of revolutions of the right rear wheel W_RR is increased.

Engagement forces of the first and second hydraulic clutches 3_R and 3_L can be continuously controlled by adjusting the magnitudes of pressures applied to the clutches and therefore, the ratio of the number of revolutions of the left rear wheel to the number of revolutions of the right rear wheel can be continuously controlled within a range determined by a ratio of teeth of the gears 14, 15, 17, 18, 20 and 21.

Returning to FIG. 1, the following signals are inputted to an electronic control unit U to which the first and second hydraulic clutches 3_R and 3_L are connected: a signal from a lateral acceleration sensor S₁ for detecting a lateral acceleration of the vehicle; a signal from a steering angle sensor S₂ for detecting a rotational angle of steering wheel 36; a signal from an intake pipe internal absolute pressure sensor S₃ for detecting an internal absolute pressure in an intake pipe of the engine E; a signal from an engine revolution-number sensor S₄ for detecting a number of revolutions of the engine E; and signals from wheel speed sensors S₅, S₆, S₇ and S₈ for detecting numbers of revolutions of the four wheels, respectively.

The operation of the embodiment of the present invention having the above-described construction will be described below.

The electronic control unit U calculates the turning amount of the vehicle from the lateral acceleration of the vehicle detected by the lateral acceleration sensor S₁, the rotational angle of the steering wheel 36 detected by the steering angle sensor S₂ and the wheel speeds of the rear wheels W_RL and W_RR detected by the wheel speed sensors S₇ and S₈. The electronic control unit U further calculates an engine torque from outputs of the intake pipe internal absolute pressure sensor S₃ and the engine revolution-number sensor S₄ and calculates a torque distributed to the left and right rear wheels W_RL and W_RR from the engine torque, the wheel speeds of the front wheels W_FL and W_FR detected by the wheel speed sensors S₇ and S₈ and the turning amount of the vehicle. Thus, the engagement forces of the first and second hydraulic clutches 3_R and 3_L are in accordance with the distributed torque.

When the vehicle is traveling at a low or medium speed, a braking force is applied to an inner one of the left and right rear wheels W_RL and W_RR and a driving force is applied to an outer one of the left and right rear wheels W_RL and W_RR during turning of the vehicle, in order to enhance the turning performance. To this end, when the vehicle is turned in a counterclockwise direction, the number of revolutions of the right rear wheel W_RR (the outer wheel during turning of the vehicle) is increased, while the number of rotations of the left rear wheel W_RL (the inner wheel during turning of the vehicle) is decreased, by bringing the second hydraulic clutch 3_L into engagement. When the vehicle is turned in a clockwise direction, the number of revolutions of the right rear wheel W_RR (the inner wheel during turning of the vehicle) is decreased, while the number of revolutions of the left rear wheel W_RL (the outer wheel during turning of the vehicle) is increased, by bringing the first hydraulic clutch 3_R into engagement.

If the number of revolutions of the outer wheel during turning of the vehicle is increased and the number of revolutions of the inner wheel is decreased in the above manner, a driving force is generated in the outer wheel having the increased number of revolutions, and a braking force is generated in the inner wheel having the decreased number of revolutions. The magnitudes of the driving force and the braking force are equal to a torque transmitting capacity transmitted by the first or second hydraulic clutch 3_R or 3_L which is in the engaged state.

When the vehicle is traveling straight ahead, the countershaft 11 connected to the right axle 1_R through the first speed-increasing gear 14, and the second speed-increasing gear 15 is rotated at a speed higher than that of the right axle 1_R and hence, the hydraulic pump 35 mounted on the countershaft 11 is driven at high speed, as compared with the case where the hydraulic pump 35 is mounted on the right axle 1_R (or the left axle 1_L). Thus, even during traveling of the vehicle at a low vehicle speed, a sufficient amount of oil discharged from the hydraulic pump 35 can be insured, and the first and second hydraulic clutches 3_R and 3_L can be reliably operated. Moreover, since the hydraulic pump 35 is mounted within the gearbox 2, oil passages connecting the hydraulic pump 35 to both of the hydraulic clutches 3_R and 3_L can be shortened.

The countershaft 11, on which the first and second hydraulic clutches 3_R and 3_L are mounted, is rotated at a speed higher than those of the left and right axles 1_L and 1_R and hence, the torque capacity to be transmitted by the first and second hydraulic clutches 3_R and 3_L is also smaller. Therefore, the first and second hydraulic clutches 3_R and 3_L can be reduced in size to reduce the size of the entire gearbox 2.

Further, the first and second hydraulic clutches 3_R and 3_L having a larger size are disposed back-to-back, and the first and third shifting gears 17 and 20 having a smaller size are disposed on the opposite sides of the first and second hydraulic clutches 3_R and 3_L. Therefore, the first and second hydraulic clutches 3_R and 3_L and the first and third shifting gears 17 and 20 can be disposed in a compact lay-out to provide a reduction in size of the gearbox 2. Moreover, the outer diameters of the first and third shifting gears 17 and 20, respectively, are less than those of the first and second hydraulic clutches 3_R and 3_L and hence, the radial sizes of the first and second hydraulic clutches 3_R and 3_L can be reduced, as compared with the case where the first and third shifting gears 17 and 20 are mounted around the outer peripheries of the clutch outer portions 22_R and 22_L.

Although the embodiment of the present invention has been described in detail, it will be understood that the present invention is not limited to the above-described embodiment, and various modifications may be made without departing from the subject matter and scope of the invention defined in claims.

For example, the system for generating the difference between the wheel speeds of the follower wheels has been described in the embodiment, but the present invention is also applicable to a system for generating a difference between wheel speeds of the driven wheels. In addition, the present invention is further applicable to a system for generating a difference between wheel speeds of driven wheels in a vehicle in which an auxiliary driving source such as an electric motor is connected to follower wheels, so that upon slipping of driven wheels, the auxiliary driving source is operated to provide a four-wheel drive state. Further, in place of the first and second hydraulic clutches 3_R and 3_L, another clutch such as an electromagnetic clutch, a fluid coupling or the like can be employed.

Claims

1. A system for generating a difference in speed between left and right wheels of a vehicle, by connecting the left and right wheels to each other by a gearbox, wherein said gearbox includes:

a countershaft disposed parallel to axles of said left and right wheels;

first and second speed-increasing gears for increasing the number of revolutions of one of said axles to transmit the rotation of the one axle to said countershaft;

a first shifting gear relatively rotatably carried on said countershaft;

a second shifting gear fixedly mounted on the other axle and meshed with said first shifting gear;

a third shifting gear relatively rotatably carried on said countershaft;

a fourth shifting gear fixedly mounted on said other axle and meshed with said third shifting gear;

a first clutch mounted on said countershaft for coupling said first shifting gear to said countershaft; and

a second clutch mounted on said countershaft for coupling said third shifting gear to said countershaft, said first and second clutches being disposed adjacent each other between said first and third shifting gears.

2. A system for generating a difference in speed between left and right wheels of a vehicle according to claim 1, wherein an outer diameter of said first shifting gear is less than an outer diameter of a clutch outer portion of said first clutch, and an outer diameter of said third shifting gear is less than an outer diameter of a clutch outer portion of said second clutch.

3. A system for generating a difference in speed between left and right wheels of a vehicle according to claim 1, further including a hydraulic pump for supplying a working oil to said first and second clutches, said hydraulic pump being driven by said countershaft.

4. A system for generating a difference in speed between left and right wheels of a vehicle according to claim 1, wherein outer diameters of said first and third shifting gears are different from each other.

5. A system for generating a difference in speed between left and right wheels of a vehicle according to claim 1, wherein said left and right wheels are follower wheels.